View
6
Download
0
Category
Preview:
Citation preview
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 145
DESIGN AND IN VITRO EVALUATION OF COLON TARGETED DRUG DELIVERY SYSTEM OF A MODEL
NSAID FOR THE TREATMENT OF INFLAMMATORY BOWEL DISEASE
M S SIVARAM1*
, ANUP KUMAR ROY1, VENKATESH DP
1, ANUDEEP BALLA
1,
SATISH KUMAR REDDY1, SADANAND REDDY
1
Corresponding Author: M S SIVARAM, Department of Industrial pharmacy, Acharya & BM Reddy
College of Pharmacy, Soldevanahalli, Hessarghatta main road, Chikkabanavara (P), Bangalore-
560107, Email- satyasivarammandipudi@gmail.com
ABSTRACT: The objective of the present research work is to formulate and optimize the colon targeted tablet formulations of Mesalamine HCl using time-dependent and natural bio degradable polymers like Chitosan, HPMC K4M and Sodium CMC as carriers. Matrix tablets containing various proportions of chitosan, HPMC K4M and sodium CMC were prepared by wet granulation technique using PVP K30 as a binder. IR spectrum showed no interaction between Mesalamine and chitosan, HPMC K4M and sodium CMC. All the formulations were evaluated for hardness, drug content uniformity, stability study and were subjected to in vitro drug release studies. The amount of Mesalamine released from the matrix tablet at different time interval was estimated by UV method. Colon targeted matrix tablets of Mesalamine containing 20% of chitosan, 70% HPMC K4M and 10% sodium CMC released 2.14% of Mesalamine in 0.1 N HCl, 6.77% in phosphate buffer pH 7.4 and 103.90% in the phosphate buffer pH 6.8 for 14 hours. The tablets are enteric coated using a combination of Eudragit L100 and Eudragit S100. The dissolution study was continued in simulated colonic fluids, the matrix tablets containing 20% chitosan, 20% HPMC K4M and 10% sodium CMC released the same amount of Mesalamine after degradation into 2-3 pieces at the end of 14h study. The colon targeted matrix tablet of Mesalamine showed no change either in physical appearance, drug content or in dissolution pattern after storage at 30ºC±2˚C / 65±5% RH for 60 days.
Keywords: Mesalamine HCl USP, Chitosan, HPMC K4M, Colon targeted matrix tablet, Enteric-coating.
1. INTRODUCTION
Among the controlled delivery systems, colon targeted drug delivery systems have been the focus of interest for the last decade, which is useful not only for local but also for systemic therapy. By definition, colonic delivery refers to targeted delivery of drugs into the lower GI tract, which occurs primarily in the large intestine (i.e. colon). The site specific delivery of drugs to lower parts of the GI tract is advantageous for localized treatment of several colonic diseases, mainly inflammatory bowel disease (Crohn’s disease and ulcerative colitis), irritable bowel syndrome, intestinal amoebiasis and colon cancer. These delivery systems when taken orally, allow drugs to release the drug from the delivery system once the delivery system arrives into the colon1, 2, 3. The drug release in the colon of the gastrointestinal tract locally accumulates the drug in a high concentration without involving absorption in the small intestine, which leads to reduction of systemic side effects. Delivery to the colon would ensure direct treatment at the disease site, lower dose with fewer systemic side effects.
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 146
In addition to local therapy, the colon can also be utilized as a portal for the entry of drugs into the systemic circulation 4-12. The term inflammatory bowel disease represents the disorders that occur in the region of small intestine and colon in which the intestines become inflamed (red and swollen), probably as a result of an immune reaction of the body against its own intestinal tissue. The disease is characterized by chronic, relapsing inflammation of the gastrointestinal tract and often are associated with extra intestinal manifestations. Inflammatory bowel disease is characterized by two symptoms Ulcerative colitis and Crohn’s disease13 . Mesalamine is an anti-inflammatory drug used for the treatment of colonic disorders like inflammatory bowel disease and in Arthritis. It reduces the inflammation by blocking the cyclooxygenase and inhibits prostaglandin production.14 The polymers Chitosan facilitates biodegradable approach and HPMC K4M facilitates time dependent approach. The usage of polymers Eudragit L100 and Eudragit S100 facilitates pH dependent approach which prevents the absorption of drug in acidic environment of stomach.
2. MATERIALS AND METHODS:
Materials Source
Mesalamine D.K. Intrachem Pvt. Ltd and BEC Chemicals Pvt. Ltd. Mumbai.
Chitosan Hi Media chemicals, Mumbai
HPMC K4M Yarrow chem, Mumbai
Sodium CMC Yarrow chem, Mumbai
Eudragit L100 and S100 Evonik India, Mumbai
PVP K-30 Karnataka fine chem, Bangalore
Magnesium stearate Karnataka fine chem, Bangalore
Talc Karnataka fine chem, Bangalore
FORMULATION OF COLON TARGETED TABLETS OF MESALAMINE
Mesalamine HCl USP, HPMC K4M, Chitosan, sodium CMC, PVP-K30, Microcrystalline Cellulose
(MCC), Magnesium stearate and Talc were taken in required quantities. Batch of 50 tablets was
prepared by wet granulation method. Dry screening of all the raw materials is done using sieve
#80. Drug in dry state was mixed with HPMC K4M (10% in ethanol) and Chitosan (1%w/v in Lactic
acid) and MCC (half quantity) and then made into granules using PVP K-30 (6% in isopropyl alcohol)
as granulating agent. Granules are then passed through sieve # 22/44. Remaining amount of
disintegrant, magnesium stearate are added to granules and then compressed to tablet using 12mm
diameter biconcave punch in 10 station Rimek minipress-I tablet punching machine and evaluated
for their physicochemical properties and for invitro release profile. The optimum batch of tablets are
enteric coated using Eudragit L100 and Eudragit S100 by dip coating method.15 The detailed
compositions of the prepared tablet formulations are given in (Table 2 and 3).
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 147
EVALUATION OF PREFORMULATION PARAMETERS:
i) Micromeretic properties16, 17, 18
a) Angle of repose
The angle of repose of granules was determined by the funnel method. The accurately weighed powder was taken in a funnel. The height (h) of the funnel was adjusted in such a way that the tip of the funnel just touches the apex of the heap of the granules. The granules are allowed to flow through funnel freely onto the surface. The diameter of the granule cone was measured and angle of repose was calculated using the following equation.
θ = tan-1h/r.
Where, θ = angle of repose, h = height of the pile and r = radius of the pile base.
b) Bulk density
Both loose bulk density (LBD) or bulk density and tapped bulk density (TBD) were determined. Granules from each formulation, previously lightly shaken to break any agglomerates formed was introduced into a 100 ml measuring cylinder. After the initial volume was observed, the cylinder was allowed to fall under its own weight onto a hard surface from the height of 2.5 cm at 2 sec intervals. The tapping was continued until no further change in volume was noted
Bulk density is calculated by using formula:
c) Carr’s index
It helps in measuring the force required to break the friction between the particles and the hopper. It is expressed in % and given by
Carr’s index (%) = *(TBD-LBD) * 100]/TBD where
LBD = weight of the powder/volume of the packing
TBD = weight of the powder/tapped volume of the packing
ii) Compatibility studies
Fourier Transform – Infrared spectroscopy (FTIR)
The FTIR spectra of pure drug, polymers and combination of drug and polymer were obtained using FTIR spectrophotometer (Bruker Optic, Tensor 27, and USA).
iii) Physicochemical parameters19
a) Tablet hardness
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 148
The resistance of tablet for shipping or breakage, under conditions of storage, transportation and handling, before usage, depends on its hardness. The hardness of tablet of each formulation was measured by using Pfizer hardness tester.
b) Tablet thickness
Thickness of tablets was important for uniformity of tablet size. Thickness was measured by using Vernier calipers on 3 randomly selected samples.
c) Friability
Friability is the measure of tablet strength. Roche Friabilator was used for testing the friability using the following procedure. Ten tablets were weighed accurately and placed in the plastic chamber that revolves at 25 rpm for 4 min dropping the tablets through a distance of six inches with each revolution. After 100 revolutions the tablets were re-weighed and the percentage loss in tablet weight was determined.
d) Weight variation
Twenty tablets were weighed individually and the average weight was determined. Then percentage deviation from the average weight was calculated. According to IP standards, not more than two of the individual weight deviates from the average weight by more than the percentage shown in the (Table 9) and none deviates by more than twice that percentage.
e) Uniformity of drug content
Ten tablets were weighed and average weight is calculated. All tablets were crushed and powder weight equivalent to 300 mg drug was dissolved in pH 6.8 Phosphate buffer solution and the volume was made up to 100 ml with pH 6.8 Phosphate buffer solution (stock-1). From the stock solution, 10 ml solution was taken in 100 ml volumetric flask and the volume was made with pH 6.8 phosphate buffer solution (stock-2). From the stock-2 solution 1 ml was taken and the volume is made up to 10 ml with pH 6.8 Phosphate buffer. The absorbance was measured spectro-photometrically at 331.5 nm against blank correction media. Amount of drug present in one tablet was calculated.
f) Dissolution studies20
The release rate of Mesalamine HCl from Chitosan matrix tablets were determined using USP dissolution testing apparatus II (paddle type). The dissolution test was performed using 900 ml of simulated gastric fluid (0.1 N HCl, 0.2% NaCl) for 2 hours, pH 7.4 Phosphate buffer saline for 3 hours and in pH 6.8 Phosphate buffer till the tablet disintegrates at 37 ± 0.5 °C and 100 rpm. Aliquot volume was withdrawn from the dissolution apparatus hourly and the samples were replaced with fresh dissolution medium. The withdrawn samples were made up to 10ml using particular buffer solutions. After filtration, the amount of drug release was determined from the standard calibration curve of pure drug at 232.5 nm (for 0.1N HCl) 329.5nm (pH 7.4 Phosphate buffer) and 331 nm (pH 6.8 Phosphate buffer).
g) Drug release kinetic studies21, 22
From time to time, various authors have proposed different types of drug release mechanisms from matrices. It has been proposed that drug release from matrices usualy implies water penetration in the matrix, hydration, swelling and diffusion of the dissolved drug. Several kinetic models relating to the drug release from matrices, selected from the most important mathematical models, are described over here. However, it is worth mention that the release mechanism of a drug would depend on the dosage form selected, pH, nature of the drug and the polymer used.
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 149
4) Stability studies for the most satisfactory formulation of colon targeted tablets of Mesalamine
Stability testing of drug products begins as a part of drug discovery and ends with the demise of the compound or commercial product. To assess the drug and formulation stability, stability studies were done according to ICH guidelines.
The stability studies were carried out of the most satisfactory formulation as per ICH guidelines. The most satisfactory formulation sealed in aluminum packaging and kept in humidity chamber maintained at 30 ± 2 °C / 65 ± 5 % RH for two months. At the end of studies, samples were analyzed for the drug content, in vitro dissolution, floating behavior and other physicochemical parameters.23
3. RESULTS
FTIR (ATR) spectrum of pure Mesalamine drug
E:\Industrial Pharmacy\SHIVARAM\MESALAMINE.4 MESALAMINE SOLID 21/12/2012
3870
.33
3731
.34
3681
.69
3485
.14
3426
.22
3001
.42
2947
.65
2769
.90
2680
.17
2546
.00
2342
.33
2006
.31
1796
.25
1646
.28
1610
.56
1573
.37
1486
.93
1446
.36
1349
.28
1315
.01
1263
.28
1237
.60
1189
.35
1131
.07
1086
.21
928.
8288
4.83
809.
8477
0.70
685.
22
615.
15
100015002000250030003500
Wavenumber cm-1
8890
9294
9698
100
Tran
smitt
ance
[%]
Page 1/1
Fig 1. FTIR (ATR) spectrum of Mesalamine+Chitosan
E:\Industrial Pharmacy\SHIVARAM\MESALAMINE+CHITOSAN.0 MESALAMINE+CHITOSAN SOLID 21/12/2012
3946
.82
3849
.15
3774
.37
3707
.68
3664
.43
3567
.97
3497
.79
3425
.83
3391
.42
3338
.97
3020
.57
2779
.97
2704
.44
2557
.42
2523
.01
2050
.85
1797
.38
1646
.45
1610
.57
1575
.42
1486
.84
1446
.51
1348
.77
1315
.79
1263
.32
1238
.84
1189
.21
1131
.80
1083
.60
930.
2488
7.67
810.
4077
1.15
685.
4165
3.15
624.
27
100015002000250030003500
Wavenumber cm-1
9394
9596
9798
9910
0
Tran
smitt
ance
[%]
Page 1/1
Fig 2. FTIR (ATR) spectrum of Mesalamine + HPMC K4M
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 150
E:\Industrial Pharmacy\SHIVARAM\MESALAMINE+HPMC K4M.0 MESALAMINE+HPMC K4M SOLID 21/12/2012
3944
.78
3871
.92
3818
.74
3752
.11
3692
.53
3629
.73
3575
.17
3496
.68
3296
.69
3007
.70
2947
.69
2773
.06
2553
.68
2042
.75
1797
.80
1737
.11
1647
.73
1612
.55
1575
.40
1488
.57
1448
.97
1351
.98
1263
.66
1241
.55
1190
.72
1135
.33
1083
.64
928.
8988
7.75
811.
2877
3.23
685.
8764
9.82
615.
32
100015002000250030003500
Wavenumber cm-1
9394
9596
9798
9910
0
Tran
smitt
ance
[%]
Page 1/1
Fig 3. FTIR spectrum of Mesalamine + Sodium CMC
E:\Industrial Pharmacy\SHIVARAM\MESALAMINE+SODIUM CMC.0 MESALAMINE+SODIUM CMC SOLID 21/12/2012
3966
.07
3749
.57
3709
.64
3648
.40
3578
.50
3509
.46
3066
.30
3001
.51
2947
.25
2894
.77
2777
.42
2555
.34
2338
.09
2052
.46
1793
.20
1751
.08
1647
.73
1610
.38
1576
.49
1486
.25
1447
.45
1350
.15
1317
.10
1264
.21
1238
.27
1189
.10
1129
.04
1083
.61
931.
7188
9.09
809.
8477
1.90
741.
5168
6.48
650.
4762
6.71
100015002000250030003500
Wavenumber cm-1
9596
9798
9910
0
Tran
smitt
ance
[%]
Page 1/1
Fig 4.FTIR spectrum of Mesalamine + Eudragit L100
E:\Industrial Pharmacy\SHIVARAM\Mesalamine+eudragit L100.0 Mesalamine+eudragit L100 solid 06/02/2013
3873
.31
3838
.05
3757
.16
3564
.49
3517
.28
3437
.00
3335
.92
3099
.49
2989
.85
2901
.38
2785
.37
2548
.19
2024
.18
1708
.01
1646
.36
1577
.82
1485
.90
1446
.93
1348
.04
1260
.53
1148
.71
926.
10
811.
6077
3.26
682.
6263
8.51
622.
56
100015002000250030003500
Wavenumber cm-1
8890
9294
9698
100
Tran
smitt
ance
[%]
Page 1/1
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 151
Fig 5. FTIR spectrum of Mesalamine + Eudragit S100
Table 1: FTIR (ATR) spectral data of Mesalamine and polymer combination
Mesalamine
Mesalamine + Chitosan
Mesalamine + HPMC
K4M
Mesalamine + Sodium
CMC
Mesalamine + Eudragit
L100
Mesalamine + Eudragit
S100
Functional Group
3485.14
3489.15
3496.88
3509.46
3437.00 3514.24
O-H stretch
3001.42
3020.57
3007.70
3001.51
2989.85 3001.18
C-H stretch
1610.56
1610.57
1612.55
1610.38
1646.36 1644.98
N-H stretch
1446.36, 1486.93
1446.51,
1486.84
1448.57,
1488.57
1446.93,
1485.90
1444.52,
1482.78
1444.52
1482.78
C-C stretch
1349.28
1348.77
1351.98
1350.15
1351.99 1351.99 O-H bend
1131.07
1131.80
1135.33
1129.04
1151.36 1151.36
C-O stretch
1189.35-1263.28
1189.21-1263.32
1190.72-1263.66
1189.10-1264.21
1260.53 1251.97 In plane bending
685.22-809.84
685.41-810.40
685.87-
811.28
686.48-809.84
682.62-811.60
687.84-812.78
C-H bond out of plane bending
*All values are in cm-1
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 152
Table 2: Detailed formulation chart of colon targeted matrix tablets of Mesalamine
INGREDIENTS F1 F2 F3 F4 F5 F6 F7
Mesalamine HCl
300 300 300 300 300 300 300
Chitosan 60 120 - 60 80 60 100
HPMC K4M 60 - 120 - 80 60 100
PVP K-30 30 30 30 30 30 30 30
Sodium CMC 60 - 40 120 40 - 30
Mg. stearate 25 25 25 25 10 25 10
Talc 25 25 25 25 10 25 10
Total weight of tablet
600 600 600 600 600 600 600
*All values are in mg
Table 3: Enteric coating formula for tablets of Mesalamine
Ingredients Quantity
Eudragit S-100 16gm
Eudragit L-100 16gm
Triethyl citrate 4gm
Acetone/Isopropyl alcohol 250gm
Evaluation of Parameters
Table 4: Micromeretic properties of granules of Mesalamine matrix tablets
Formulation code
Precompression properties
Bulk density (gm/ml)
Tapped density (gm/ml)
Angle of repose (º)
Compressibility index
(%)
Hausner’s ratio
F1 0.35 ± 0.01 0.36 ± 0.009 31.56 ± 0.47 15.88 ± 1.20
1.02 ± 0.01
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 153
* All values are mean of 3 readings ± SD
Table 5: Physicochemical parameters of colon targeted enteric coated tablets of Mesalamine
Formulation code
Tablet properties
Hardness * (kg/cm2)
Thickness *(mm)
Friability
(%)
Weight variation * (mg)
Drug content
(%)
F1
6.5 ± 0.35
6.06 ± 0.17
0.182 600.77 ± 1.18
91.90
F2
6.2 ± 0.11
6.02 ± 0.12
0.251 601.45 ± 0.82
99.04
F3
6.4 ± 0.15
6.12 ± 0.11
0.477 604.15 ± 1.06
99.35
6.4 ± 0.17 0.276 601.87 ± 2.80
F2 0.39 ± 0.005 0.39 ± 0.002 34.36 ± 0.40 10.66 ± 1.05
1.01 ± 0.03
F3 0.45 ± 0.02 0.52 ± 0.008 32.28 ± 1.47 12.66 ± 1.27
1.14 ± 0.09
F4 0.55 ± 0.004 0.60 ± 0.007 34.60 ± 0.26 10.25 ± 1.19
1.09 ± 0.04
F5 0.52 ± 0.005 0.56 ± 0.006 30.05 ± 0.17 10.45 ± 0.008
1.09 ± 0.001
F6 0.53 ± 0.005 0.35 ± 0.004 28.36 ± 0.06 18.42 ± 0.088
1.05 ± 0.001
F7 0.58 ± 0.005 0.59 ± 0.06 27.98 ± 0.20 10.10 ± 0.10
1.11 ± 0.012
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 154
F4
6.01 ± 0.10
91.26
F5
6.2 ± 0.15
6.05 ± 0.02
0.334 600.95 ± 2.83
101.61
F6
6.1 ± 0.15
5.9 ± 0.10
0.36 592.17 ± 2.77
104.57
F7
6.1 ± 0.05 6.03 ± 0.02 0.569 598.85 ± 2.04
99.74
* All values are mean of 3 readings ± SD
Table 6: Comparative drug release profiles of formulation F1-F4
Sl No Time (H) Cumulative % Drug Release ± SD
1 F1 F2 F3 F4
2 0.5 3.78±0.84 6.86±2.12 6.22±0.71 6.69±2.0
3 1 5.96±2.60 8.25±3.02 8.63±2.54 7.81±2.95
4 1.5 7.09±2.73 10.38±3.41 10.56±1.02 10.15±2.04
5 2 9.56±3.75 13.33±2.34 12.65±1.79 14.04±1.24
6 3 5.83±2.81 8.12±0.03 13.76±2.41 11.36±0.04
7 4 8.64±2.13 9.89±1.13 16.32±1.16 17.22±3.39
8 5 14.01±0.6 13.85±1.94 28.14±2.49 23.50±1.91
9 6 19.67±0.21 18.73±2.51 16.29±1.75 16.16±1.98
10 7 30.41±2.05 27.75±2.33 25.06±1.29 32.04±2.40
11 8 46.95±4.08 39.01±1.97 37.24±1.45 48.71±0.94
12 9 71.52±1.54 48.02±1.52 53.30±2.80 66.13±1.04
13 10 93.47±3.43 60.95±3.52 67.23±2.76 83.31±0.71
14 11 110.26±2.35 77.01±0.68 92.26±2.60 94.98±1.07
15 12 - 95.34±2.63 103.36±2.54 102.55±1.85
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 155
16 13 - - - -
17 14 - - - -
* All values are mean of 3 readings ± SD
Table 7: Comparative drug release profiles of formulation F5-F7
Sl No Time (H) Cumulative % Drug Release ± SD
1 F5 F6 F7
2 0.5 0.67±0.65 4.21±1.76 3.18±2.79
3 1 1.14±0.30 7.81±2.95 3.96±3.43
4 1.5 1.35±0.30 10.15±2.04 5.07±4.39
5 2 2.14±0.31 14.04±1.24 5.63±4.87
6 3 3.83±1.20 8.83±2.29 19.14±6.19
7 4 4.09±1.19 12.62±1.4 23.53±7.33
8 5 6.77±2.01 16.11±5.08 27.77±5.64
9 6 9.02±0.98 16.92±3.20 27.82±5.88
10 7 19.69±1.22 29.55±2.67 35.08±7.00
11 8 28.64±0.22 39.70±3.50 45.59±6.82
12 9 41.70±1.98 54.33±2.58 53.93±5.82
13 10 57.56±2.07 67.15±2.08 66.20±9.19
14 11 77.98±2.05 82.86±2.20 82.62±1.04
15 12 88.95±2.98 108.86±2.78 95.70±1.71
16 13 99.46±2.42 - 99.90±0.65
17 14 103.90±0.80 - -
* All values are mean of 3 readings ± SD
Comparative drug release profiles of F1-F7 colon targeted Mesalamine tablets
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 156
0
20
40
60
80
100
120
0 2 4 6 8 10 12 14
%C
DR
TIME IN H
DISSOLUTION DATA
F1 F2 F3 F4 F5 F6 F7
Table 8: Drug release kinetic studies based on different kinetic models
Formulation code
Zero order First order Higuchi model Peppas model
r 2 r 2 r 2 N r 2 N
F5 0.978 0.867 0.740 33.62 0.917 1.658
The in vitro release data obtained were fitted into various kinetic models. Correlation coefficients of formulation F5 showed higher correlation with zero order plots than first order, Higuchi model and Peppas model. The ‘n’ value was found to be 1.658 which corresponds to super case-II transport or release system. So, predominant drug release mechanism was found to be of sustained and case-II (Non-Fickian) type.
Table 9: Physicochemical parameters of most satisfactory formulation F5 during/after stability studies
Time in days Formulation code Hardness (kg/cm2) Drug content (%)
0 F5 6.2±0.15 101.61
30 (A) F5 6.2±0.11 100.79
60 (B) F5 6.0±0.18 100.14
A= 30 ± 2˚C/ 65 ± 5% RH
B = 40 ± 2˚C/ 75 ± 5% RH
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 157
Table 10: Drug release profile for most satisfactory formulation F5 during stability studies
Sl No
Time (h) AFTER 30 DAYS AFTER 60 DAYS
F5 (%) ± SD F5 (%) ± SD
1 0.5 1.67±0.22 1.77±1.14
2 1 2.22±0.58 2.45±1.38
3 1.5 2.31±1.55 2.74±1.59
4 2 2.85±1.74 3.21±1.54
5 3 3.77±1.26 3.97±2.15
6 4 4.24±1.03 4.82±1.54
7 5 7.03±1.37 6.97±1.25
8 6 10.15±0.80 10.74±2.07
9 7 20.23±0.58 19.72±1.19
10 8 27.91±1.56 27.75±1.74
11 9 42.15±2.18 43.57±1.03
12 10 55.76±2.71 59.24±1.45
13 11 78.34±0.75 79.47±0.52
14 12 89.65±1.7 88.14±2.57
15 13 99.85±0.78 100.57±1.27
16 14 102.78±0.95 102.17±1.48
*All values are mean of 3 trails ± SD
Fig 7. In vitro drug release profile of F5 after stability studies
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 158
4. DISCUSSSION
In the present study, an attempt was made to formulate colon targeted matrix tablets of Mesalamine HCl USP using a combination of natural polysaccharide Chitosan and time dependent methacrylic polymer HPMC K4M as carriers to deliver the drug directly into the colon. The tablets are enteric coated using Eudragit L100 and S100 to prevent the drug release in the stomach. A total of seven formulations of matrix tablets of Mesalamine HCl was prepared by wet granulation method. The preformulation studies such as bulk density, tapped density, angle of repose, compressibility index and Hausner ratio were evaluated which were found to be within prescribed limits and indicated good to poor flowing property. The data obtained from physicochemical parameters such as hardness, friability, weight variation, drug content and in vitro drug dissolution are shown in table (4, 5 and 6).
Preformulation studies
Estimation of Mesalmine HCl USP was carried out by using SHIMADZU-1700 UV spectrophotometer at λmax of 232.5 nm in 0.1N HCl (pH 1.2) and in Phosphate buffers pH 6.8 and pH 7.4 at λmax of 329.5 and 331nm respectively. The linear coefficients were found closer to 1. By using the regression coefficient equation, the drug content and % CDR were calculated.
UV spectrum analysis of Mesalamine HCl USP
Mesalamine HCl USP showed maximum absorption at a wavelength 232.5 nm in 0.1N HCl and in Phosphate buffers pH 6.8 and pH 7.4 at 329.5 and 331 nm respectively. Standard calibration curve when subjected to regression analysis, the value of regression coefficient was found to be 0.999 and 0.998 which showed linear relationship between concentration and absorbance.
Any formulation development work has to be preceded by preformulation studies. This preformulation study includes drug polymer compatibility study and analytical investigation of the drug. FTIR (ATR) studies showed that there was no interaction between drug and polymer. So, the drug and polymers were found to be compatible.
Formulation development
The matrix tablets of Mesalamine HCl were prepared by wet granulation technique using 10 % PVP K-30. Microcrystalline cellulose was used as diluent and the mixture of talc and magnesium stearate at 1:1 ratio was used as lubricant. The composition of different matrix formulation used in the study containing 300 mg of Mesalamine is given in table 2. In the present study, chitosan and HPMC K4M were incorporated at various percentages to retard the drug release in the environment of stomach and small intestine. The granules were prepared by the method of wet granulation. The drug release in stomach is prevented by enteric coating using a combination of Eudragit L100 and Eudragit S100.
Micromeretic properties
Angle of repose
The angle of repose value for formulation F1 – F7 ranged from 27.98 ± 0.20 to 34.60 ± 0.26° (table 4) which indicate the good flow properties of granules.
Bulk density and Tapped density
The value of bulk density and tapped density for formulation F1 – F7 ranged from 0.35 ± 0.01 to 0.58 ± 0.005 gm/ml and 0.35 ± 0.004 to 0.60 ± 0.007 gm/ml respectively (table 4).
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 159
Compressibility index
The compressibility index values for formulation F1 – F7 ranged from 10.10 ± 0.10 to 18.42 ± 0.08 % (table 4). These values indicate that the granules of all batches exhibited excellent to fair characters and hence, they were suitable for wet granulation.
Evaluation of physicochemical properties
Tablet Hardness
Hardness of the developed formulations varied from 6.1±0.15 to 6.5±0.35 kg/cm2 (table 5) in all formulations indicating good mechanical strength with an ability to withstand physical and mechanical stress condition while handling.
Thickness
Thickness for all formulations varied from 5.9±0.10 mm to 6.12±0.11 mm (table 5) and the average thickness was within the range of ± 5%. Each sample was analyzed in triplicate.
Friability
The loss in total weight of the tablets due to friability was in the range of 0.1 to 0.5 % (table 5) in all the formulation and the friability value was less than 1% which ensured that formulated tablets were mechanically stable.
Weight variation
The average weight of 20 tablets was calculated for formulation F1 – F7 and it varies from 592.17±2.77 to 604.15±1.06 mg (table 5) and none of the formulations showed a deviation more than ± 5 % for any of the tablets tested which complied with the official limit of the IP.
Uniformity of drug content
The amount of drug present for formulation F1 – F7 ranged from 91.26 to 104.57 (table 5) which is within the official limit of IP i.e. 85 - 115%.
In vitro drug release studies
All the colon targeted matrix tablet formulations of Mesalamine were evaluated for in vitro dissolution studies as per the procedure described in above section. In the formulation F1, The highest in vitro dissolution profile at the end of 14 h (103.90%) was shown by F5 containing 2:2:1 of Chitosan, HPMC K4M and Sodium CMC respectively (table 7) and F7 containing 2:1:2 ratio of Chitosan, HPMC K4M and Sodium CMC showed 99.90% (table 7) and the other formulations like F2 containing only Chitosan showed 99.34% only in 5 h in intestinal conditions and F3 containing only HPMC K4M showed 103.36% only in 5 h in intestinal conditions (table 6).
From the in vitro dissolution studies it can be discussed that the colon targeted matrix tablets containing 2:2:1 ratio of Chitosan, HPMC K4M and sodium CMC respectively as the best formulation to target Mesalamine to the colon in the treatment of inflammatory bowel disease. It may be due to the presence of colonic bacteria which act on the Chitosan and digests it.
Kinetics modeling of drug release profile
The in vitro release data obtained were fitted in to various kinetic models and the best formulation was selected. The correlation coefficient of formulation F5 batch was higher for zero order plots (table 8) than first order, Higuchi model and Peppas model. The ‘n’ value was found to be 1.658
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 160
which corresponds to non Fickian case 2 transport system. So, predominant release mechanism was found to be of sustained and non Fickian case 2 transport system.
Stability study
The optimized formulation (F5) was subjected for accelerated stability studies. Tablet is packed in aluminum foil and kept in humidity chamber maintained at 30 ± 2 °C/65 ± 5 % RH for 60 days. Samples were withdrawn at the interval of 1 month and were analyzed for the hardness, drug content and in vitro release rate (table-28 and 27). There was no statistically significant difference in hardness, drug content and in vitro release pattern at various sampling points during the stability studies.
5. Conclusion
The objective of the present study was to develop a polymeric combination for colon targeted tablets of Mesalamine HCl USP and to implement a design of experiments principle in developing formulation for better stability and high production feasibility and excellent patient acceptability.
The micromeretic evaluation such as angle of repose, compressibility index and Hausner ratio showed good to satisfactory flow properties. The physicochemical evaluation of different formulations were carried out as per IP and the results obtained were in accordance with IP limits. Various formulations were developed by using release retarding and gel forming polymers like HPMC K4M, Chitosan and Sodium CMC in single by wet granulation method. Different proportions of Chitosan and HPMC was associated with decrease in overall cumulative drug release rate. The highest viscosity polymeric combination (20% Chitosan with 70% HPMC K4M and 10% Sodium CMC-F5 batch) has seen to inhibit the initial burst release of Mesalamine. From the result, it is evident that Chitosan and HPMC by forming a matrix retards the release rate of drug. In the formulation F5, Chitosan (20% of tablet weight) and HPMC (70% of tablet weight) were used. F5 showed 103.90% drug release in 14 h and initial drug release was minimized by enteric coating. Based on the result obtained it concluded that Chitosan, HPMC K4M and Sodium CMC is suitable to get desired release pattern.
The in vitro release data obtained were fitted in to various kinetic models and the best formulation was selected. The correlation coefficient of formulation F5 batch was higher for zero order plots (table 8) than first order, Higuchi model and Peppas model. The ‘n’ value was found to be 1.658 which corresponds to non Fickian case 2 transport system. So, predominant release mechanism was found to be of sustained and non Fickian case 2 transport system. The most satisfactory formulation F5 was subjected to short term stability studies by placing in varied conditions for sixty days. It was concluded that there was no significant changes in drug content or physical properties. The in vitro drug release of formulation F5 showed no noticeable changes confirming that the formulation was stable after a period of 60 days.
6. REFERENCES
[1]. Himanshu G, Dinesh B, Aarti S. Recent trends in oral drug delivery: A review [online]
[cited 2013 Jan 24]. Available from URL: http://www. eurekaselect.com. (2012)
[2]. Abdul B, John B. Perspectives on Colonic Drug Delivery, Business Briefing, Pharmatech
:185–90. (2003).
[3]. Philip AK, Philip B. Colon targeted drug delivery systems: A review on primary and novel
approaches. Oman Med J ;25:70-8. (2010).
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 161
[4]. John Wiley. Colon targeted drug delivery systems. In: Edith Mathiowitz, editor.
Encyclopedia of controlled drug delivery 2nd Ed. New York: American Scientific
publishers; p. 698-726. (2003)
[5]. Sarasija S, Hota A. Colon specific drug delivery systems, Ind J Pharm Sci 2000;62(1):1-8.
[6]. Chourasia MK, Jain SK. Pharmaceutical approaches to colon targeted drug delivery. J Pharm Sci ;6(1):33-66. (2003).
[7]. Libo Yang, James S Chu, Joseph A. Colon-specific drug delivery: New approaches and in vitro/ in vivo evaluation. Int J Pharm ;235:1-15. (2002).
[8]. Peter JW, Lisbeth I. Colonic drug delivery. Drug Dev Ind Pharm ;23(9):893-913. (1997).
[9]. Aurora J, Talwar N, Vinayak P. Colonic drug delivery challenges and opportunities-An overview. Eur Gastroenterol Hepatol Rev ;45:1-6. (2006).
[10]. Chourasia MK, Jain SK. Pharmaceutical approaches to colon targeted drug delivery. J Pharm Sci ;6(1):33-66. (2003).
[11]. Sandrakim MD, Georgeferry MD. Inflammatory bowel disease in children. Curr Probl Pediatr ;32:103-32. (2002).
[12]. Inflammatory bowel disease: [online]. [cited 2013 Feb 13]; Available from URL:http://emedicine.medscape.com/article/179037. (2002).
[13]. Goracinova K, Glavas DM, Simonoska CM, Geskovski N. Drug targeting in IBD treatment existing and new approaches.
[14]. Dash AK, Brittain HG. Analytical profile of drug substances. Vol:25. New Jersey Publishers;209-39. (1998).
[15]. Madhu S, Joshi B, Monika B, Manish G. Formulation and evaluation of colon targeted tablets of Mesalazine. J Drug Del Therap;2(5):24-36. (2012).
[16]. (cited on 2012 Sep 12). Available from
URL:http://www.pharmacopoeia.cn/v29240/usp29nf24s0_c1174.html. (2010).
[17]. Vijaya RM, Sudeesh E, Sravanakumar K. Design and evaluation of Mesalamine tablet for colon specific delivery. Int J Drug Dev Res ; 3(3):197-212. (2011).
[18]. Leon Lachmann, A. Herbert Liebermann. The theory and practice of industrial pharmacy. Special Indian edition. CBS publishers, New Delhi.183-4. (2009).
[19]. Indian Pharmacopoeia. Government of India, Ministry of Health and Family Welfare. 6th Ed. Indian Pharmacopoeia commission, Ghaziabad;1:189-93. (2010).
[20]. Chuang MC, Christensen JM, James WA. New dissolution methods for Mesalamine tablets and capsules. Dissol Technol ;15(3):7-13. (2008).
[21]. Shoaib MN, Tazeen J, Hamid AM, Rabia IY. Evaluation of drug release kinetics from Ibuprofen matrix tablets using HPMC. Pak J Pharm Sci ;19(2):119-24. (2006).
[22]. Gautam Singhvi, Mahaveer Singh. In vitro drug release characterization models. Int J
M.S.Sivaram. et.al/ 1(2) 145-162 2013
International Journal of Pharmacy and Engineering (IJPE) Page 162
Pharm Res ;2(1):77-84. (2011).
[23]. Note for guidance on stability testing. Stability testing of new drug substances and
products.[cited 2013 Feb 13]; Available from
URL: http://www.ema.europa.eu /pdfs/human/ich/2136992n.pdf.
Recommended